I have been trying to write `mfix`

down using `Control.Arrow.loop`

. I came up with different definitions and would like to see which one is `mfix`

's actual workalike.

So, the solution I reckon to be the right one is the following:

```
mfix' :: MonadFix m => (a -> m a) -> m a
mfix' k = let f ~(_, d) = sequenceA (d, k d)
in (flip runKleisli () . loop . Kleisli) f
```

As one can see, the `loop . Kleisli`

's argument works for `Applicative`

instances. I find it to be a good sign as we mostly have our knot-tying ruined by `(>>=)`

's strictness in the right argument.

Here is another function. I can tell that it is not `mfix`

's total workalike, but the only case I found is *not very natural*. Take a look:

```
mfix'' k = let f ~(_, d) = fmap ((,) d) (return d >>= k)
in (flip runKleisli () . loop . Kleisli) f
```

As far as I understand, not every strict on the right-hand bind forces its argument entirely. For example, in case of `IO`

:

```
GHCi> mfix'' ((return :: a -> IO a) . (1:))
[1,1,1,1,1,Interrupted.
```

So, I decided to fix this. I just took `Maybe`

and forced `x`

in `Just x >>= k`

:

```
data Maybe' a = Just' a | Nothing' deriving Show
instance Functor Maybe' where
fmap = liftM
instance Applicative Maybe' where
pure = return
(<*>) = ap
instance Monad Maybe' where
return = Just'
Nothing' >>= k = Nothing'
Just' x >>= k = x `seq` k x
instance MonadFix Maybe' where
mfix f = let a = f (unJust' a) in a
where unJust' (Just' x) = x
unJust' Nothing' = errorWithoutStackTrace "mfix Maybe': Nothing'."
```

Having this on our hands:

```
GHCi> mfix ((return :: a -> Maybe' a) . (1:))
[1,1,1,1,1,Interrupted.
GHCi> mfix' ((return :: a -> Maybe' a) . (1:))
[1,1,1,1,1,Interrupted.
GHCi> mfix'' ((return :: a -> Maybe' a) . (1:))
Interrupted.
```

So, here are my questions:

- Is there any other example which could show that
`mfix''`

is not totally`mfix`

? - Are monads with such a strict bind, like
`Maybe'`

, interesting in practice? - Are there any examples which show that
`mfix'`

is not totally`mfix`

that I have not found?

**A small side note on IO:**

```
mfix3 k' =
let
k = return . k'
f ~(_, d) = fmap ((,) d) (d >>= k)
in (join . flip runKleisli () . loop . Kleisli) f
```

Do not worry about all the `return`

s and `join`

s - they are here just to have `mfix3`

's and `mfix`

's types match. The idea is that we pass `d`

itself instead of `return d`

to the `(>>=)`

on the right-hand. It gives us the following:

```
GHCi> mfix3 ((return :: a -> IO a) . (1:))
Interrupted.
```

Yet, for example **(thanks to Li-yao Xia for their comment)**:

```
GHCi> mfix3 ((return :: a -> e -> a) . (1:)) ()
[1,1,1,1,1,Interrupted.
```

**Edit: thanks to HTNW for an important note on pattern-matching in the comments: it is better to use \ ~(_, d) -> ..., not \ (_, d) -> ....**

`fix'`

is almost`mfix`

. Comparing it to yours, I think you're missing some laziness (you use`\(_, d) ->`

while I use`\~(_, d) ->`

(hidden inside`snd`

), which may or may not be important. Don't actually have the answers here, but thought it might be interesting. Also,`Maybe'`

is not a monad:`return undefined >>= const x`

should be`x`

but is`undefined`

. Of course, that doesn't stop us from doing it (e.g. I think MTL's`Writer`

is similarly not a monad)...`(print >> return) = return`

. This is`(>>)`

in the reader monad, which ignores its first argument, so this has nothing to do with IO. These examples are not demonstrating what you think they're demonstrating.`IO`

- thank you. Yet please note that`mfix3 (return . (1:))`

is not a bottom for every monad. For example,`mfix3 ((return :: a -> e -> a) . (1:)) ()`

produces output. I will edit the post so it is not confusing.